一种新型静电激励单晶硅谐振器,以厚度-伸展模式振动

M. Ivan, B. Dulmet, G. Martin, S. Ballandras
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引用次数: 7

摘要

本文提出了一种基于标准硅片的静电驱动BAW谐振器的新结构,正在申请专利。利用厚度扩展(TE)模式,在400 μ m厚的硅晶圆上产生接近10 MHz的基频。该器件基于单端口设计,具有1 μ m的间隙,并叠加直流电压偏置和较小幅度的交流激励。与传统的依靠结构共振的条形和板形MEMS谐振器相比,我们的谐振器被设计为使用TE波的能量捕获来优化Q因子。该结构基本上由单个(100)硅板组成,p掺杂并通过标准阳极键合键合到康宁玻璃基板上。通过反应离子蚀刻在玻璃层中加工出静电激发所需的薄间隙。进行了广泛的电气和机械特性分析。它们与理论分析预测的行为相当吻合。为了更好地获得运动参数,需要对大的静态电容进行补偿。在基本te模式上观察到的Q因子接近9000,对于频率源应用具有足够的耦合。使用谐振器稳定射频振荡器仍在开发中。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
New electrostatically-excited single crystal silicon resonator vibrating in a Thickness-Extensional mode
This paper presents a new patent-pending structure of BAW resonator built on standard silicon wafer and driven by electrostatic force. Thickness-Extensional (TE) modes are exploited, yielding a fundamental frequency near 10 MHz with a 400µm-thick Si wafer. The device is based on a one-port design featuring a 1µm gap submitted to a superimposition of a DC voltage bias and a lesser-amplitude AC excitation. In contrast with conventional bar and plate MEMS resonators relying on structural resonances, our resonators are designed to use an energy-trapping of the TE waves to optimize the Q factor. The structure essentially consists of a single (100) Silicon plate, p-doped and bonded onto a Corning glass substrate by standard anodic bonding. The thin gap required for the electrostatic excitation is machined in the glass layer by Reactive Ion Etching. Extensive electrical and mechanical characterisations were performed. They match rather well the behavior predicted by the theoretical analysis. A compensation of the large static capacitance is needed to give a better access to the motional parameters. Q factors near 9000 have been observed on the fundamental TE-mode, with a sufficient coupling for frequency source applications. The stabilization of a RF oscillator using the resonators is still under development.
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